- ホーム
- > 洋書
- > ドイツ書
- > Mathematics, Sciences & Technology
- > Technology
- > mechanical engineering & production engineering
Full Description
Hydraulic Servo-systems details the basic concepts of many recent developments of nonlinear identification and nonlinear control and their application to hydraulic servo-systems: developments such as feedback linearisation and fuzzy control. It also reviews the principles, benefits and limitations associated with standard control design approaches such as linear state feedback control, feedforward control and compensation for static nonlinearities, because of their continued practical importance. Featuring: theoretical (physically based) modelling of hydraulic servo-systems; experimental modelling (system identification); control strategies for hydraulic servo-systems; case studies and experimental results. Appendices outline the most important fundamentals of (nonlinear) differential geometry and fuzzy control. The book is very application-oriented and provides the reader with detailed working procedures and hints for implementation routines and software tools.
Contents
1 Introduction.- 1.1 Historical View and Motivation for Hydraulic Systems.- 1.2 Aims and Focus of the Book.- 1.3 Outline of the Chapters.- 1.4 Background of the Work and Bibliographical Notes.- 2 General Description of Hydraulic Servo-systems.- 2.1 Basic Structure of Hydraulic Servo-systems.- 2.2 Description of the Components.- 2.3 Classification of Hydraulic Servo-systems.- 2.4 Measurement and Control Devices.- 2.5 Application Examples.- 3 Physical Fundamentals of Hydraulics.- 3.1 Physical Properties of Fluids.- 3.2 General Equations of Fluid Motion.- 3.3 Flow Through Passages.- 3.4 Spool Port Forces.- 3.5 Electro-hydraulic Analogy.- 4 Physically Based Modelling.- 4.1 Introduction.- 4.2 Elementary Models.- 4.3 Typical Non-linear State-space Models.- 4.4 Structured and Simplified Models of Valve-controlled Systems.- 4.5 Determination of Specific Model Parameters.- 4.6 Implementation and Software Tools.- 4.7 Section Summary.- 5 Experimental Modelling (Identification).- 5.1 Introduction.- 5.2 Pre-identification Process.- 5.3 Overview of Model Structures.- 5.4 Description of Selected Non-linear Model Structures.- 5.5 Parameter Estimation Methods.- 5.6 Optimisation Algorithms.- 5.7 Grey-box Identification ofNon-linear Hydraulic Servo-system Models.- 5.8 Fuzzy Identification.- 5.9 Identification with Artificial Neural Networks.- 6 Hydraulic Control Systems Design.- 6.1 Introduction.- 6.2 Classical Feedback Control Design.- 6.3 Estimator-based State Feedback Control.- 6.4 Extensions to Linear Feedback Control.- 6.5 Feedback Linearising Control.- 6.6 Approaches Similar to Feedback Linearisation.- 6.7 Fuzzy Control.- 6.8 Neural-network-based Control.- 6.9 Vibration Damping Control.- 6.10 State Estimation.- 6.11 Implementation and Software Tools.- 6.12 Rapid Prototyping Tools for Control.- 6.13 Section Summary.- 7 Case Studies and Experimental Results.- 7.1 Identification and Control of a Synchronising Cylinder.- 7.2 Modelling and Control of a Small Differential Cylinder.- 7.3 Control of a Big Differential Cylinder.- 7.4 Vibration Damping Control for a Flexible Robot.- 7.5 Vibration Damping Control for a Concrete Pump.- Appendix A Fluid Power Symbols.- Appendix B Data and Catalogue Sheets.- Appendix C Non-linear Control Background.- References.